TITANIA-SILICA GLASS WITH UNIFORM HYDROXYL CONCENTRATION

Organization Name

CORNING INCORPORATED

Inventor(s)

Michael John Campion of Corning NY (US)

Sergey Nikolaevich Shubin of Espoo (FI)

Pushkar Tandon of Painted Post NY (US)

TITANIA-SILICA GLASS WITH UNIFORM HYDROXYL CONCENTRATION - A simplified explanation of the abstract

This abstract first appeared for US patent application 18411231 titled 'TITANIA-SILICA GLASS WITH UNIFORM HYDROXYL CONCENTRATION

The process described in the abstract involves forming a titania-silica glass body by subjecting a titania-doped silica soot body to a specific thermal treatment.

• The first step in the process is exposing the titania-doped silica soot body to a thermal treatment at a temperature between 800°C and 1100°C for a calculated duration.
• This thermal treatment is crucial for the formation of the titania-silica glass body.
• The specific temperature and duration are essential for achieving the desired properties in the final glass body.
• The process likely involves additional steps beyond the initial thermal treatment to complete the formation of the glass body.
• The innovation lies in the precise control of temperature and duration during the thermal treatment to create a high-quality titania-silica glass body.

Potential Applications: - Optical components - Photovoltaic devices - High-temperature resistant materials

Problems Solved: - Achieving a uniform titania-silica glass body - Controlling the properties of the glass body through thermal treatment

Benefits: - Enhanced optical properties - Improved durability and resistance to high temperatures - Potential for use in various industries such as electronics, telecommunications, and aerospace

Commercial Applications: Title: Advanced Titania-Silica Glass for Optical and High-Temperature Applications This technology could be used in the production of optical lenses, solar panels, and protective coatings for high-temperature environments. The market implications include increased demand for specialized glass materials in industries requiring high-performance components.

Prior Art: Further research can be conducted on the thermal treatment of titania-doped silica soot bodies to explore existing patents and publications in the field of glass manufacturing and materials science.

Frequently Updated Research: Researchers may be investigating alternative methods for enhancing the properties of titania-silica glass bodies, such as novel doping techniques or post-treatment processes.

Questions about Titania-Silica Glass: 1. How does the thermal treatment process impact the properties of the titania-silica glass body? The thermal treatment process plays a crucial role in determining the optical and mechanical properties of the glass body by influencing its structure and composition.

2. What are the key differences between titania-doped silica glass and traditional silica glass? Titania-doped silica glass offers improved optical and thermal properties compared to traditional silica glass, making it suitable for specialized applications in various industries.

Original Abstract Submitted

A process of forming a titania-silica glass body, the process including exposing a titania-doped silica soot body to a first thermal treatment by heating the body to a first temperature T1 between about 800° C. and about 1100° C. for a first time duration t1 calculated using the equation: